Investigations of an Electrochemical Basis for the Protection of Steel

Mar 27, 2009 - Department of Chemistry, New York City College of Technology-CUNY, 300 Jay Street, Brooklyn, NY 11201-1909. Smart Coatings II. Chapter ...
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Chapter 15

Investigations of an Electrochemical Basis for the Protection of Steel and Aluminum by Polyaniline and Polyphenylene Ether Coatings Peter Spellane Department of Chemistry, New Y o r k City College of Technology-CUNY, 300 Jay Street, Brooklyn, N Y 11201-1909

The use of inherently conductive polymers (ICPs) in anti­ -corrosion coatings for metals is presented with emphasis on polyaniline (PANI); a mechanism for metal protection, based on the oxidation - reduction chemistry of PANI and the passivity of steel or aluminum, is described. We have also examined the non-conductive polymer poly(2,6-dimethylphenylene ether) (PPE) and present evidence that PPE applied as thin coatings on aluminum coupons ( A l 2024T3 and Al6061T6) enhances the metal's resistance to corrosion. Enhanced corrosion resistance is evident in salt-fog exposure test data and supported by D C anodic polarization curves of PPE-coated aluminum. We propose that coatings that comprise either PANI or PPE alter the surface chemistry of active-passivemetals in a way that enables the metals to form better, more protective oxides, that is, that PANI and PPE protect substrate metals through a form of anodic protection. Recent reports concerning the use of ICPs in metal protection are surveyed, and new ideas for ICP-based smart coatings are presented.

288

© 2009 American Chemical Society

289

Inherently Conductive or "Conjugated" Polymers in Coatings The 2000 Nobel Prize for Chemistry was awarded to Professors Alan Heeger, Alan MacDiarmid, and Hideki Shirakawa for "the discovery and development of conductive polymers," materials that have enormous commercial potential (1-4). In retrospect, Heeger, MacDiarmid, and Shirakawa's process of invention seems simple: combining their expertises, they prepared transpolyacetylene, the simplest macromolecule that has alternating single and double "conjugated" π-bonds, and added halogen to oxidize the polymer. Removing one or several electrons from the delocalized π-orbitals created mobile charge carriers. Polymers of this kind are called "inherently" conductive because their carriers of electronic charge move in molecular orbitals of the polymer itself rather than in conduction bands of additives such as graphite or metal flake. This paper concerns the use of inherently conductive polymers (ICPs) in a large and environmentally-important application, as active ingredient in protective coatings for metals, that is, as potential replacements for the widely used but hazardous hexavalent chromium corrosion inhibitors. We describe how ICPs can react with substrate metal and ambient oxygen to function in smart protective coatings for metals. We review the history of polyaniline coatings on metals, report our measurements of electrochemical effects of polyaniline coatings on steel and both electrochemical and salt fog testing of polyphenylene ether coatings on aluminum. We review work from several other labs toward development of smart ICP coatings for metals. The ICPs have been welldocumented (5-6) and their significance as smart materials recently surveyed (7). A review of corrosion control by ICPs, including accounts of important initial investigations, appeared in 2003 (8).

Commercially-Produced ICPs and Metal Protection Polyacetylene (PA) is the simplest of the ICPs, the easiest to draw but the most difficult to handle. PA is unstable in air and is not in any commercial sense important. Conjugated resins that are easily-handled, produced on commercial scale, and finding use in various high-value applications include polyaniline (PANI), substituted-polythiophenes (PT), and polyphenylene vinylenes (PPV). Molecular structures of fragments of these are represented in Figure 1. On its rediscovery as a conductive polymer, physicists and chemists examined PANI. PANI is easy to prepare, but it is a complex material, with several accessible oxidation states and acid-base chemistry. "Emeraldine" polyaniline has approximately equal numbers of imine and amine nitrogen atoms; polyanilineemeraldine base (PANI-EB) is represented in Figure 1.

290

Figure 1. Fragments of commercially available ICPs, polyaniline (upper), polythiophene (middle), andpolyphenylene vinylene flower).

Addition of H to each diimino-quinone group in the polymer yields the fully reduced "leucoemeraldine" polyaniline. The electrically-conductive form of PANI is prepared by protonation of PANI-EB. Applications for conductive polyaniline include antistatic coatings and conductive inks and adhesives. Several polythiophenes, with different pendant groups, are available. The poly(3,4-ethylenedioxythiophene) (PEDOT), shown here in its non-oxidized form, is produced by H . C. Starck, a division of Bayer Material-Science. Applications for PT include use in antistatic coatings and high-conductivity coatings, and as components of organic light emitting diodes, luminescent materials, and organic field effect transistors. Polyphenylene vinylene (PPV) can form highly ordered crystalline films; its applications include as electroluminescent material in organic light emitting diodes. The instability of metals in air, their tendency to react with ambient oxygen to form metal oxides, creates a problem to producers and users of metal parts and an opportunity for chemists and electrochemists. Essentially every metal part intended for structural or functional use is coated for protection, and "coating" is almost invariably a multi-step process. Metal parts are usually pretreated (prepared for painting) with protective chemical conversion coatings, which are formed in situ in the chemical reactions of acid salts with metal 2

291 surfaces. Phosphate conversion coatings are formed when for example steel is sprayed with a dilute zinc or manganese acid orthophosphate solution. A conversion coating may be saturated with oils or corrosion inhibitors or used as formed to promote the adhesion of paint. Zinc or zinc-aluminum surfaces are often treated with chromate coatings, formed when the metal is immersed in an acidified chromate solution. The paints that coat most metal articles can provide protection in several ways: barrier coatings prevent oxidants from contacting substrate metal; cathodic paint formulations provide zinc or aluminum metal as sacrificial anode to maintain the integrity of substrate metal; inhibitive paint coatings, typically comprising S r C r 0 or other inorganic oxidant, react with substrate metal to maintain a protective metal oxide surface. "Active-passive" metals, described more fully below, can form metal oxide surfaces that protect bulk metal. These include some metals of the greatest commercial importance: steel, copper, titanium, and aluminum. In principle, electrochemically-active polymer coatings can be engineered to oxidize activepassive metals and promote the reactions that lead to formation of protective metal oxide surfaces. ICPs may also be useful as sensors components of smart coatings: because corrosion and metal protection involve redox chemistry, ICPs could be designed to monitor the integrity of substrate metal, generating observable signals from electrochemical changes taking place at the surface of the metal. 4

Polyaniline: Indications of Metal Protecting Effects Polyaniline is among the earliest of industrial polymers, a by-product of the aniline dye industry in the 19 century, and probably the very first electroactive polymer. In 1862, a London physician reported electrochemical deposition of "a thick layer of dirty bluish-green pigment" on a platinum anode immersed in an acidic solution of aniline (9). The pigment was not identified as polyaniline, which was yet to be described, but the details in the report make almost certain that it was indeed PANI. The material's preparation, acid-base behavior, and redox properties were noted. Thus, one finds both a sophisticated in situ preparation of a new coating material and a description of the material's "smart" chemistry in a report that predates by about 40 years an understanding of the material's molecular nature (10-13) and by more than a century an examination of its efficacy in metal protection. D. W. DeBerry reported in 1985 that stainless steels might be protected from acid corrosion by polyaniline coatings (14). DeBerry proposed, " A form of anodic protection may be obtained by coating an active/passive metal with a redox species capable of maintaining the native oxide on the metal." DeBerry had electro-coated stainless steel electrodes in perchloric acid with polyaniline and identified the "smart" character of the material: the electroactive form of th

292 PANI appeared to be continuously regenerated by oxygen, a redox chemistry that could enable the long-term stability of PANI-coated metal. Examination of polyaniline in anti-corrosion coatings intensified after 1991. A N A S A Conference Paper (75) was followed by reports from W - K Lu, R. L . Elsenbaumer, and B . Wessling (16-17), Yen Wei at Drexel University (18), Arthur Epstein and colleagues at the Ohio State University (19-20), and from our laboratory at Akzo Nobel Chemicals (27). Evidence of oxidation-reduction chemistry between polyaniline and substrate metals supported DeBerry's earlier report. X P S data indicate that emeraldine PANI, in either base or protonated form, can be reduced by substrate steel to the leucoemeraldine state and reoxidized by air to the emeraldine state, suggesting that a polyaniline coating could enhance an active-passive metal's ability to react with oxygen to form a metal-protecting oxide surface, as indicated in Figure 2. A Monsanto group proposed an alternative mechanism for metal protection by ICPs (22): ICPs shift the site of oxygen reduction from the metal-coating interface into the bulk polymer, thereby reducing the delamination of coatings caused by reduction products.

Figure 2. Reduction by metal of polyaniline-emeraldine base (PANI-EB) to polyaniline-leucoemeraldine base (PANI-LEB), indicated by arrow down, and air oxidation of PANI-LEB to PANI-EB, indicated by up arrow.

Recent Work Concerning ICPs in Metal-Protecting Coatings Much of the newest work in the development of ICP-based anti-corrosion coatings for metals involves hybrid systems, coating formulations that combine

293 a functional ICP with another agent of metal protection. The dopants that enable electrical conductivity in ICPs affect the polymers' anti-corrosion performance, an effect that has been described and reviewed by Wallace and colleagues (23). Kinlen and colleagues reported (24) that phosphonic acid-dopant enhances polyaniline's anti-corrosion efficacy. Both Kendig (25) and Kinlen (26) have reported the controlled release of organic inhibitor, triggered by changes in potential at surfaces of polyaniline-coated copper and copper-rich aluminum, provides metal protection. Rohwerder and coworkers reported electro-chemically-triggered release of inhibitor achieved by incorporation of polypyrrole nanoparticles in coating formulations (27). Several recent patents claim that ICPs enhance the cathodic protection afforded by coatings that incorporate sacrificial anodes such as zinc or aluminum (28-29). Like some of the earliest reports of polyaniline on metal, with PANI coatings formed electrochemically, some very recent reports also describe metal protection with ICP coatings formed electrochemically on metal surfaces (30-34).

Metal Passivation: Spontaneous Metal Protection by Metal Oxide Coatings In the process of passivation, "active-passive" metals spontaneously form surface oxides that, to some degree, adhere to bulk metal and protect the metal from further oxidation. Descriptions of the process can be found in the corrosion engineering textbooks (35-37). Metal passivation is the phenomenon that slows the thermodynamically-favored oxidations of steel, aluminum, and titanium and, in some cases, enables even uncoated metals to maintain structural integrity for years. Metal passivation can be driven electrochemically as for example in the "anodization" of aluminum. The passivation of an active-passive metal is demonstrated in D C potentiodynamic current-voltage curves. As increasingly positive (anodic) voltages are applied to an active-passive substrate metal, current between the working and counter electrodes varies over several orders of magnitude, producing a currentvoltage curve that approximates the idealized I-V curve shown in Figure 3. As bias voltage is scanned anodically, current density finds a minimum at the open-circuit potential (E c). Current density increases exponentially at bias positive of E c> until it changes abruptly at the "passivating potential" (E ), indicating a transition from the metal's active to passive regimes. In the passive region, the metal resists further oxidation, even under increased bias, as indicated by the nearly constant current density. At very strong anodic bias, the oxide degrades, and the metal undergoes rapid oxidation in its "transpassive" region. 0

0

PP

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Figure 3. Idealized current voltage curve indicating active-passive behavior of some metals. Eoc and E are open circuit andpassivatingpotentials. Active, passive, and transpassive regions are indicated. PP

Experimental Section: DC Potentiodynamic Measurements of Polymer-Coated Steel or Aluminum and Salt Fog Corrosion Testing of PPE-Coated Aluminum Preparation of P A N I or P P E Coatings on Metal Samples Steel and aluminum coupons were coated with polyaniline-emeraldine base (PANI-EB) or with poly(2,6-dimethylphenylene ether) (PPE) for evaluation of each resin's effectiveness in protecting metals. PANI-EB was prepared in lab in the ammonium persulfate oxidation of aniline. In the potentiodynamic tests reported here, PANI-EB powder had been added as a pigment to a coating formulation, dispersed mechanically in a conventional epoxy-melamine primer. Cold rolled steel coupons were obtained from A C T Laboratories, Inc. Hillsdale, M I 49242. Metal coupons were scrubbed with 400 grit sandpaper and wiped with acetone or 2-butanone-saturated paper towel. Aluminum coupons (A16061T6, 03x06x0.032 inches, cut only unpolished, product number APR20754, and A12024T3 03x06x0.025 inches, cut only unpolished, product number APR24796) were obtained from A C T Laboratories, Inc. The coupons were cleaned with acetone, abraded with 400 grit sandpaper, wiped again with acetone, then bar-coated with a solution of PPE, 10% (w/w) in toluene. The poly(2,6-dimethylphenylene ether) solutions were prepared by adding 10 grams G E Blendex BHPP820 (GE Specialty Chemicals, now Chemtura, Parkersburg, W V ) slowly to 90 grams toluene. With heating, gold colored solutions were obtained. The PPE solutions were filtered through 0.45 μ PTFE or polyethylene filters and barcoated on the coupons with a #24 wire-wound

295 rod. The coated samples were dried at in air at room temperature or baked in ovens for 10 minutes at 90-95 °C or 200-210 °C then cooled by immersion in water. Coatings prepared in this way were determined, with an Elcometer 300 coating thickness gauge, to have thicknesses between 1 and 3 μπι.

Potentiodynamic Current—Voltage Curves In earlier work, we adapted D C potentiodynamic methods, typically used to characterize uncoated metal alloys, to characterize metal surfaces coated with formulations that did or did not contain chromate inhibitors (38). We have used the same technique to study metal coated with ICPs as neat coatings or in formulations. In these measurements, coated surfaces were scored with a knifeedge to ensure exposure of approximately 1 cm of metal surface to electrolyte solution. The experimental configuration is diagrammed in Figure 4. 2

SCE reference electrode counter electrode potentiostat ^ glass cylinder 4— electrolyte solution working electrode^ coated metal sample with score mark Figure 4. Diagram of electrochemical cell used to measure DC potentiodynamic current - voltage curves for coated metal substrates.

Salt Fog Corrosion Testing To examine the performance of polyphenylene ether resin as an anticorrosion coating, we have at various times coated steel, copper, titanium, and aerospace aluminum by spray- or bar-coating substrate metal with toluene solutions of the resin. In other studies, we added PPE as a pigment to standard primer formulations. Salt fog testing ( A S T M Β 117) and evaluations of aluminum panels coated with thin neat PPE, were performed at D L Laboratories (New York, N Y ) . Panels were observed daily for 5 days and evaluated for blistering ( A S T M D 714), corrosion (visual inspection), and salt deposition (visual inspection), and graded according to this A S T M score system:

296 Rating 10 9 8 6 4 2 0

Performance perfect excellent very good good fair poor no value

Effect none trace very slight slight moderate considerable complete failure

NOTES:

* ** 9F

Cannot be ascertained because of severity of corrosion and/or salt deposit. Blister area observed as a corrosion site. Type 9 blister, frequency few.

Results Section: Electrochemical and Performance Testing of PANI-EB or PPE as Coatings on Steel or Aluminum Potentiodynamic Measurements of PANI-EB-coated Cold Rolled Steel Using a D C potentiodynamic method to characterize the passivity of coated steel (38), we measured the current-voltage curves for cold rolled steel coated with either clear epoxy-melamine primer or epoxy-melamine primer with ca. 10% polyaniline-EB. The curves shown in Figure 5 suggest that polyaniline-EB fortifies the native passivity of cold rolled steel: the I-V curve of the PANIcoated steel sample has a more distinct passive region than does the steel that is coated with "clear" (unpigmented) epoxy-melamine. We infer from these measurements that polyaniline changes the metal's surface properties. While the polyaniline coating appears to fortify the metal's passivity, this effect alone does not indicate enhanced corrosion resistance, which depends on the values of open circuit potential and current density.

Salt Fog and D C Potentiodynamic Measurements of PPE-coated Aluminum PANI-EB is a non-conductive form of polyaniline. Having observed that PANI-EB appeared to improve steel's passivity, we reasoned that the origin of polyaniline's action could be the polymer's redox chemistry rather than its electrical conductivity; this reasoning led us to test polyphenylene ether (PPE) as a protective coating. Poly(2,6-dimethylphenylene ether) is not conductive; the material finds commercial application mainly as a resin for thermoplastics (39). It blends well with polycarbonate, polystyrene, and other commercial resins; it is used in plastic liners and housings for electronics including computers

297 2.500 τ M—

Φ LU

2.000 -

ω

1.500 --

>

_ c φ ο û.

1.000 0.500 0.000 -0.500 Ι -1.000 i -8.0

-7.0

-6.0

-5.0

-4.0

-3.0

Log Current Density (A/cm2)

Φ LU

ω >

"(0 Ο CL

-6.0

-4.0

2.0

log current measured (A)

Figure 5. DC potentiodynamic F V curves for steel coated with clear epoxy melamine primer (upper) or with epoxy melamine with PANI-EB (lower).

and televisions, kitchen and personal care appliances, and numerous automotive applications. Several early (40-43) and more recent (44-47) reports describe metals coated with PPE resins or claim PPE's effectiveness in protecting metal. The molecular structures of polyaniline-leucoemeraldine (PANI-LEB) and poly(2,6-dimethylphenylene ether) are compared in Figure 6. Note that oxidation of either polymer can be reversed by reduction by the metal. Results of A S T M Β 117 testing of A16061T6 and A12024T3 aluminum panels coated with neat poly(2,6-dimethylphenylene ether) are presented here; blistering, corrosion, and salt deposition data appear in Tables 1, 2, and 3. Results presented in Table 2 have appeared in an earlier form (47). The thicknesses of coating on panels whose tests are reported here had not been measured, but the coating of an identically-prepared A12024T3/PPE sample was determined with an Elcometer 300 Coating Thickness Gauge, to be 2.30 +/1.0 micrometer.

298 H

Figure 6. Comparison of the molecular structures of leucoemeraldine— polyaniline and poly (2,6-dimethylphenylene ether).

Table 1. B L I S T E R I N G During A S T M B117 Exposure

Al 6061T6

Al 2024T3

Bake temp

Day 1

Day 2

Day 3

Day 4

Day 5

No coating

RT

10

*

*

*

*

PPE

90C

9F



**

**

**

PPE

90C

9F

**

**

**

**

PPE

204C

10

10

10

10

10

PPE

204C

10

10

10

10

10

No coating

RT

*

*

*

*

PPE

90C

10

9F

9F

9F

9F

PPE

90C

10

10

10

10

10

PPE

204C

10

10

10

10

10

PPE

204C

10

10

10

10

10

299 Table 2. CORROSION during ASTM B117 Exposure

Al 6061T6

Al 2024T3

Bake temp

Day 1

Day 2

Day 3

Day 4

Day 5

No coating

RT

8

4

2

0

0

PPE

90C

10

9

9

9

8

PPE

90C

10

9

9

8

8

PPE

204C

9

9

9

8

8

PPE

204C

9

9

9

8

8

No coating

RT

0

0

0

0

0

PPE

90C

9

9

8

8

6

PPE

90C

9

9

9

8

6

PPE

204C

9

9

8

8

6

PPE

204C

8

8

8

8

6

SOURCE: Reproduced with permission from reference 47. Copyright 2000 Electrochemical Society, Inc.)

Table 3. SALT DEPOSITION during ASTM B l 17 Exposure

Al 6061T6

Al 2024T3

Bake temp

Day 1

Day 2

Day 3

Day 4

Day 5

No coating

RT

6

2

0

0

0

PPE

90C

10

10

10

10

10

PPE

90C

10

10

10

10

10

PPE

204C

10

10

10

10

10

PPE

204C

10

10

10

10

10

No coating

RT

0

0

0

0

0

PPE

90C

10

10

10

8

6

PPE

90C

10

10

10

9

9

PPE

204C

10

10

8

8

8

PPE

204C

10

9

8

8

8

300 On the basis of the resin's structural similarity to polyaniline-LEB and the air-instability of each polymer, we propose that 1-electron oxidation of the terminal dimethylphenol to a quinone-like end-group allows the PPE polymer to act as an active and renewable agent of metal passivation. Note that a similar quinoid radical is proposed to be an intermediate in the oxidative polymerization that leads to formation of polymer. A mechanism of protection is proposed in Figure 7. DC potentiodynamic measurements of aerospace aluminum A12024T3 coated with thin, neat PPE coatings produced current-voltage curves that suggest that PPE enhances the metal's passive state: the open circuit potential is higher, the onset of the transpassive region at higher bias voltage, and current density in the transpassive region lower, in the PPE-coated sample than in the epoxycoated sample. See Figure 8. On the basis of these potentiodynamic current-voltage data, and with the support of salt fog performance data, we propose that coatings that comprise either PANI or PPE can alter the surface chemistry of active-passive metals in a way that enables the metals to form better, more protective surface oxides.

Work in Progress: Even Smarter ICP Coatings Because ICP coatings successfully combine what have been traditionally distinct functions of metal coatings, adherent protective barrier and anticorrosion agent, and because the polymers can be chemically modified and offer environmental advantage, it is reasonable to call them "smart." Indeed, in some of the newest formulations, coatings that contain ICPs use the polymer's response to environmental conditions to trigger more aggressive protection by other components: very smart. A very smart and actively-protective coating would somehow remediate its imperfections or perceive and report any incipient problems. The latter of these smart functions is the goal of our current work: we seek to develop sensor compounds that can monitor coating performance. Our goal is optically- or electronically-addressable low-cost coatings that can report the early stages of metal oxidation. We have begun by dispersing ροφίινπη compounds in coatings. The porphyrins are a family of stable macrocyclic aromatic compounds whose optical properties are well-characterized. Ροφπντίηβ and metal-chelated metalΙοροφ1ννπη5 have highly characteristic optical absoφtion and emission properties. For example, the presence of a metal ion, such as Z n , can be verified by the optical properties of the ηιβι^ΙΙοροφΓίνπη compound it forms. ++

Figure 7. A proposed mechanism for metal protection: air oxidation of PPE coating on metal substrate creates a quinoid radical that can oxidize the metal.

metal with protective oxide

oxidation by polymer

metal

302

Figure 8. DC Potentiodynamic current - voltage curves, A12024T3 coated with clear epoxy (upper) or with neat PPE (lower).

303 In recent years, porphyrin compounds have been used in smart coating applications. Luminescent metalloporphyrin compounds, particularly the tetraperfluorotetraphenylporphyrin (TFPP) compounds, have been developed as optical sensors of airflow. The intensity and lifetime of optical luminescence of these porphyrins are inverse functions of 0 pressure (48). These porphyrinbased "pressure paints" are smart coatings that are used in aerospace research and development to monitor airflow over aircraft surfaces. Our current research involves synthetic chemistry: we want to bond conjugated sidechains to porphyrin compounds, to integrate optically-observable porphyrins into the electronic structures of ICP coatings. Porphyrin compounds with conjugated sidechains are also investigated for their ability to separate charge or transfer excited state energy under photo-excitation. These porphyrinconjugated oligomer compounds hold promise of being materials with extraordinary stability and utility in electronic applications (49-51). 2

References 1. 2. 3. 4. 5.

6. 7. 8.

9. 10. 11. 12. 13. 14. 15.

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